System and method for channel-adaptive antenna selection

ABSTRACT

Systems and methods that provide channel-adaptive antenna selection in multi-antenna element communication systems are provided. In one embodiment, a method that selects a subset of receive antennas of a receiver to receive a transmitted RF signal may include, for example, one or more of the following: establishing possible subsets of the receive antennas; determining sets of channel parameter statistics corresponding to the possible subsets of the receive antennas; computing output bit error rates of the receiver, each output bit error rate being computed based on at least one set of channel parameter statistics; selecting a particular possible subset of the receive antennas based upon a criterion predicated on the computed output bit error rates; and connecting one or more RF chains of the receiver to the receive antennas of the selected particular possible subset.

CROSS-REFERENCE TO RELATED APPLICATIONS/INCORPORATION BY REFERENCE

The present application is a CONTINUATION of U.S. application Ser. No. 13/209,968, filed Aug. 15, 2011, now U.S. Pat. No. 8,401,591 which is a CONTINUATION of U.S. application Ser. No. 12/953,005, filed Nov. 23, 2010, now U.S. Pat. No. 8,000,746, which is a CONTINUATION of U.S. application Ser. No. 12/418,091, filed Apr. 3, 2009, now U.S. Pat. No. 7,840,235, which is a CONTINUATION of U.S. application Ser. No. 10/979,992, filed Nov. 3, 2004, now U.S. Pat. No. 7,515,939, which is a CONTINUATION-IN-PART of U.S. application Ser. No. 10/957,398, filed Oct. 1, 2004, now U.S. Pat. No. 7,483,718. U.S. application Ser. No. 10/957,398 makes reference to, claims priority to and claims benefit from U.S. Application No. 60/507,843, filed Oct. 1, 2003. U.S. application Ser. No. 10/979,992 makes reference to claims priority to, and claims benefit from U.S. Application No. 60/519,398, filed Nov. 12, 2003.

U.S. application Ser. No. 13/209,968 is also related to U.S. application Ser. No. 12/360,489, filed Jan. 27, 2009, issued U.S. Pat. No. 7,890,145, and U.S. application Ser. No. 13/027,702, filed Feb. 15, 2011, issued as issued U.S. Pat. No. 8,036,711. Each of the above-identified applications are hereby incorporated herein by reference in their entireties.

BACKGROUND OF THE INVENTION

Most current wireless communication systems are composed of nodes configured with a single transmit and receive antenna. However, for a wide range of wireless communication systems, it has been predicted that the performance, including capacity, may be substantially improved through the use of multiple transmit and/or multiple receive antennas. Such configurations form the basis of “smart” antenna techniques. Smart antenna techniques, coupled with space-time signal processing, can be utilized both to combat the deleterious effects of multipath fading of a desired incoming signal and to suppress interfering signals. In this way both the performance and capacity of digital wireless systems in existence or being deployed (e.g., CDMA-based systems, TDMA-based systems, WLAN systems, and OFDM-based systems such as IEEE 802.11a/g) may be improved.

At least some of the impairments to the performance of wireless systems of the type described above may be at least partially ameliorated by using multi-element antenna systems designed to introduce a diversity gain and suppress interference within the signal reception process. This has been described, for example, in “The Impact of Antenna Diversity On the Capacity of Wireless Communication Systems”, by L H. Winters et al., IEEE Transactions on Communications, vol. 42, no. 2/3/4, pages 1740-1751, February 1994. Such diversity gains improve system performance by mitigating multipath for more uniform coverage, increasing received signal-to-noise ratio for greater range or reduced required transmit power, and providing more robustness against interference or permitting greater frequency reuse for higher capacity.

Within communication systems incorporating multi-antenna receivers, a set of M receive antennas may be capable of nulling up to M−1 interferers. Accordingly, N signals may be simultaneously transmitted in the same bandwidth using N transmit antennas, with the transmitted signal then being separated into N respective signals by way of a set of N antennas deployed at the receiver. Systems of this type are generally referred to as multiple-input-multiple-output (MIMO) systems, and have been studied extensively. See, for example, “Optimum combining for indoor radio systems with multiple users”, by J. H. Winters, IEEE Transactions on Communications, vol. COM-35, no. 11, November 1987; “Capacity of Multi-Antenna Array Systems In Indoor Wireless Environment”, by C. Chuah et al., Proceedings of Globecom '98 Sydney, Australia, IEEE 1998, pages 1894-1899 November 1998; and “Fading Correlation and Its Effect on the Capacity of Multi-Element Antenna Systems” by D. Shiu et al., IEEE Transactions on Communications, vol. 48, no. 3, pages 502-513, March 2000.

Some multi-element antenna arrangements (e.g., some MIMOs) provide system capacity enhancements that can be achieved using the above-referenced configurations. Under the assumption of perfect estimates of the applicable channel at the receiver, in a MIMO system the received signal decomposes to M “spatially-multiplexed” independent channels. This results in an M-fold capacity increase relative to single-antenna systems. For a fixed overall transmitted power, the capacity offered by MIMOs scales linearly with the number of antenna elements. Specifically, it has been shown that with N transmit and N receive antennas an N-fold increase in the data rate over a single antenna system can be achieved without any increase in the total bandwidth or total transmit power. See, e.g., “On Limits of Wireless Communications in a Fading Environment When Using Multiple Antennas”, by G. J. Foschini et al., Wireless Personal Communications, Kluwer Academic Publishers, vol. 6, no. 3, pages 311-335, March 1998. In experimental MIMO systems predicated upon N-fold spatial multiplexing, more than N antennas are often deployed at a given transmitter or receiver. This is because each additional antenna adds to the diversity gain arid antenna gain and interference suppression applicable to all N spatially-multiplexed signals. See, e.g., “Simplified processing for high spectral efficiency wireless communication employing multi-element arrays”, by G. J. Foschini et al., IEEE Journal on Selected Areas in Communications, vol. 17, issue 11, November 1999, pages 1841-1852.

Although increasing the number of transmit and/or receive antennas enhances various aspects of the performance of MIMO systems, the provision of a separate RF chain for each transmit and receive antenna increases costs. Each RF chain is generally comprised a low noise amplifier, filter, downconverter, and analog-to-digital converter (A/D), with the latter three devices typically being responsible for most of the cost of the RF chain. In certain existing single-antenna wireless receivers, the single required RF chain may account for in excess of 30% of the receiver's total cost. It is thus apparent that as the number of transmit and receive antennas increases, overall system cost and power consumption may dramatically increase.

Some attempts to address these shortcomings may be found, for example, in United States Patent Publication No. 20020102950 entitled “Method and apparatus for selection and use of optimal antennas in wireless systems”; “Capacity of MIMO systems with antenna selection”, by A. Molisch et al., Proceedings of IEEE ICC, Helsinki, Finland, June 2001, vol. 2, pp. 570-574; and “On optimum MIMO with antenna selection”, by R. S. Blum et al., IEEE Communications Letters, vol. 6, issue 8, August 2002, pages 322-324, in which a subset of transmit/receive antennas are selected from a larger number of antennas. Since with N-fold spatial multiplexing, at least N RF chains must be used, typically N out of M total antennas would be chosen at the receiver and/or N out of n_(T) total antennas would be chosen at the transmitter, with M>N and n_(T)>N.

The performance of a system with antenna selection depends, for example, on the criteria used in the selection process. Different criteria used even under the same charm' condition may well result in a different selected subset of antennas, thereby yielding different performances. Some of the above-reference, documents advocate the maximum capacity criterion to select the antenna subset. However, capacity is an idealized quantity that may be an unachievable bound because it may necessitate perfect coding and/or equalization and/or continuous modulation. In practice, the equalizer is not ideal, limited coding (or even no coding) and quantized modulation is used.

BRIEF SUMMARY OF THE INVENTION

Some embodiments according to some aspects of the present invention may relate to systems and methods that provide channel-adaptive antenna selection in multi-antenna-element communication systems.

In one embodiment according to some aspects of the present invention, a system that selects N antenna elements in an M-antenna-element transmitter or an M-antenna-element receiver, in which N is less than M, may include, for example, M antenna elements in the M-antenna-element transmitter or the M-antenna-element receiver, N RF chains, and a switch coupled to the N RF chains. The M-antenna-element receiver may compute an output bit error rate for each possible N antenna element subset of the M antenna elements. Each output bit error may be computed based on at least one set of channel parameter statistics. The M-antenna-element receiver may select the particular N antenna element subset based on a criterion predicated on the computed output bit error rates. In response to the selection of the particular N antenna element subset based on the criterion, the switch may couple the N RF chains to the N antenna elements of the particular N antenna element subset.

In another embodiment according to some aspects of the present invention, a method that selects a subset of receive antennas of a receiver to receive a transmitted RF signal may include, for example, one or more of the following: establishing possible subsets of the receive antennas; determining sets of channel parameter statistics corresponding to the possible subsets of the receive antennas; computing output bit error rates of the receiver, each output bit error rate being computed based on at least one set of channel parameter statistics; selecting a particular possible subset of the receive antennas based upon a criterion predicated on the computed output bit error rates; and connecting one or more RF chains of the receiver to the receive antennas of the selected particular possible subset.

In another embodiment according to some aspects of the present invention, a method that selects a subset of transmit antennas of a transmitter to transmit an RF input signal as a plurality of RF output signals that are subsequently received by a receiver, may include, for example, one or more of the following: establishing possible subsets of the transmit antennas; determining sets of channel parameter statistics corresponding to the possible subsets of the transmit antennas; selecting transmission modes respectively corresponding to the sets of channel parameter statistics; computing output bit error rates of the receiver, each output bit error rate being computed based on at least one set of channel parameter statistics and at least one selected transmission mode; selecting a particular possible subset of the transmit antennas based on a criterion predicated on at least the computed output bit error rates; and connecting one or more RF chains of the transmitter to the transmit antennas of the selected particular possible subset.

In yet another embodiment according to some aspects of the present invention, in a communication system including a transmitter and a receiver, the transmitter including transmit antennas adapted to transmit a set of spatially-multiplexed RF output signals through a channel using two or more transmit RF chains, the receiver including receive antennas adapted to receive the set of spatially-multiplexed RF output signals and adapted to responsively generate a set of spatially-multiplexed received RF signals that is processed by two or more receive RF chains, an antenna selection method may include, for example, one or more of the following: establishing possible subsets of the transmit antennas and possible subsets of the receive antennas; determining sets of channel parameter statistics corresponding to combinations of the possible subsets of the transmit antennas and the possible subsets of the receive antennas; selecting transmission modes respectively corresponding to the sets of channel parameter statistics; computing output bit error rates of the receiver, each output bit error rate being computed based on at least one set of channel parameter statistics and a corresponding selected transmission mode; selecting a particular possible subset of the transmit antennas and a particular possible subset of the receive antennas based on a criterion predicated on at least the computed output bit error rates; connecting the two or more of the transmit RF chains to the selected particular possible subset of the transmit antennas; and connecting the two or more receive RF chains to the selected particular possible subset of the receive antennas.

In yet still another embodiment according to some aspects of the present invention, in a communication system including a transmitter and a receiver, the transmitter including transmit antennas adapted to transmit a set of RF output signals through a channel using one or more transmit RF chains, the receiver including receive antennas adapted to receive the set of RF output signals and adapted to responsively generate a set of received RF signals that is processed by one or more receive RF chains, an antenna selection method may include, for example, one or more of the following: establishing possible subsets of the transmit antennas and possible subsets of the receive antennas; determining sets of channel parameter statistics corresponding to combinations of the possible subsets of the transmit antennas and the possible subsets of the receive antennas; selecting transmission modes respectively corresponding to the sets of channel parameter statistics; computing output bit error rates of the receiver, each output bit error rate being computed based on at least one set of channel parameter statistics and a corresponding selected transmission mode; selecting a particular possible subset of the transmit antennas and a particular possible subset of the receive antennas based on a criterion predicated on at least the computed output bit error rates; connecting the one or more of the transmit RF chains to the selected particular possible subset of the transmit antennas; and connecting the one or more receive RF chains to the selected particular possible subset of the receive antennas.

These and other features and advantages of some embodiments—according to some aspects of the present invention may be appreciated from a review of the following detailed description, along with the accompanying figures in which like reference numerals refer to like parts throughout.

BRIEF DESCRIPTION OF THE DRAWINGS/FIGURES

1A-B show an embodiment of a conventional MIMO communication system.

FIGS. 2A-B show an embodiment of a MIMO system according to some aspects of the present invention.

FIG. 3 shows an embodiment of an SM-MIMO-OFDM system according to some aspects of the present invention.

FIGS. 4A-B show flowcharts illustrating embodiments of an antenna selection method according to some aspects of the present invention.

FIG. 5 shows a graph illustrating exemplary performance results according to some aspects of the present invention.

FIG. 6 shows an embodiment of an SC-MIMO-OFDM system according to some aspects of the present invention.

FIG. 7 shows an embodiment of a receiver in a DS-SS SIMO system according to some aspects of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Overview of Some Aspects of the Present Invention

Some embodiments according to some aspects of the present invention may relate to communication systems that use a transmitter and/or a receiver that have multiple antenna elements.

Some embodiments according to some aspects of the present invention may relate to systems and methods that provide channel-adaptive antenna selection in multi-antenna-element communication systems.

Some embodiments according to some aspects of the present invention may be implemented to facilitate a selection of a subset of antenna elements in one or more multi-antenna wireless communication devices based on a criterion predicated, at least in part, on computed output bit error rates.

Some embodiments according to some aspects of the present invention may be implemented to facilitate the selection of a subset of antenna elements in one or more multi-antenna wireless communication devices so as to minimize or to optimize, for example, a bit error rate (BER).

Some embodiments according to some aspects of the present invention may be implemented to facilitate a channel-adaptive selection of a subset of antenna elements in one or more multi-antenna wireless communication devices based on a criterion predicated, at least in part, on computed output bit error rates.

Some embodiments according to some aspects of the present invention may enable the use of a greater number of antenna elements than the number of radio frequency (RF) chains. Some embodiments according to some aspects of the present invention may enhance system performance in a cost-effective manner.

Some embodiments according to some aspects of the present invention may be employed to select a subset of antenna elements of a multi-antenna transmitter to transmit a signal and/or to select a subset of antenna elements of a multi-antenna receiver to receive a signal.

Some embodiments according to some aspects of the present invention may provide that a selection of the subset of antenna elements is predicated, at least in part, upon a criterion based, at least in part, on at least computed output bit error rates.

Some embodiments according to some aspects of the present invention may provide that the selection of the subset of antenna elements is predicated, at least in part, upon a minimization of a BER.

Some embodiments according to some aspects of the present invention may be applicable to communications systems that employ, for example, code division multiple access signals, spread spectrum signals, single carrier signals, multiple carrier signals, orthogonal frequency divisional multiplexed signals, ultra-wideband signals, space-time diversity signals and spatially-multiplexed signals.

Some embodiments according to some aspects of the present invention may provide that a selection of the subset of antenna elements be predicated, at least in part, upon a minimization of a BER based on, for example, parameters (e.g., statistical parameters) related to one or more communication channels. Some embodiments according to some aspects of the present invention may provide that a selection of a subset of antenna elements be predicated upon minimization of a BER that is computed based, at least in part, on parameter statistics of one or more applicable communication channels.

Some embodiments according to some aspects of the present invention may be used for antenna selection in a multiple-input-multiple-output (MIMO) communication system. The MIMO communication system may provide, for example, a transmitter that broadcasts a plurality (N) of spatially-multiplexed signals through N transmit antenna elements selected from a set of n_(T) antenna elements, where n_(T)>N. The MIMO communication system may provide, for example, a receiver in which N receive antenna elements, selected from a total of M elements where M>N, form a number of output signals equal to the number of spatially-multiplexed signals. The output signals are in turn provided to corresponding RF chains for processing at baseband. Thus, some embodiments according to some aspects of the present invention may advantageously permit minimization of BER (e.g., channel-adaptive minimization of BER) and/or reduction of RF signal processing costs within multiple-antenna systems.

Some embodiments according to some aspects of the present invention may provide a transmitter including one or more RF chains and a particular plurality of transmit antennas, which may be all or less than all of the transmit antennas of the transmitter. Some embodiments according to some aspects of the present invention may provide a system and/or a method that, for example, selects a subset of a particular plurality of transmit antennas, the subset transmitting an RF input signal, for example, as a plurality of RF output signals subsequently received, for example, by a receiver. A plurality of possible subsets (e.g., all or less than all of the possible subsets comprising a particular number of transmit antennas or other types of grouping characteristics) of the particular plurality of transmit antennas may be established. Sets of channel parameter statistics or other parameters corresponding to the possible subsets of the particular plurality of transmit antennas may then be determined. Transmission modes or other types of modes corresponding to respective sets of channel parameter statistics may be selected. Transmission modes may include, for example, a modulation level and/or a coding rate. A plurality of BERs (e.g., output BERs) of the receiver, for example, may be computed. Each of the plurality of output BERs, for example, may be computed based, at least in part, upon, for example, a set of channel parameter statistics and/or corresponding selected transmission modes. A possible subset of the particular plurality of transmit antennas may be selected based upon, for example, criteria predicated, at least in part, upon the output BERs and/or the selected transmission modes. One or more RF chains may then be connected to the transmit antenna or antennas of the selected possible subset of the particular plurality of transmit antennas.

Some embodiments according to some aspects of the present invention may provide for channel parameter statistics that may include, for example, first-order statistics, second-order statistics or higher-order statistics. Channel parameter statistics may include, for example, one or more of the following: an output signal-to-noise ratio, an output signal-to-interference-and-noise ratio, a likelihood ratio (e.g., a log-likelihood ratio), a Euclidean distance in a signal constellation, for example, of a receiver. Channel parameter statistics may be computed, for example, over a frequency domain or a time domain.

Some embodiments of an antenna selection method according to some aspects of the present invention may be used with different types of multi-antenna communication systems. In particular embodiments, some embodiments of an antenna selection method according to some aspects of the present invention may be applied, for example, to a multi-antenna receiver within a “single channel” (SC) system (e.g., a system without spatial multiplexing), to a multi-antenna transmitter in a single channel system, or to the transmitter and/or receiver of a MIMO system employing spatial multiplexing (SM) or single channel.

Some embodiments according to some aspects of the present invention may provide, for example, a number N of receive antenna elements that are selected from a set of M available antenna elements (where M>N) such that the selected subset of antenna elements minimizes the BER, for example, when various channel parameter statistics are taken into account. This may be effected by establishing possible subsets of a plurality of transmit antennas and possible subsets of the M receive antennas. The method further includes determining plural sets of channel parameter statistics corresponding to combinations of ones of the possible subsets of the plurality of transmit antennas and ones of the possible subsets of the plurality of receive antennas. Plural transmission modes respectively corresponding to the plural sets of channel parameter statistics are then selected. In addition, plural output bit error rates of the receiver are computed based at least in part upon one of the plural sets of channel parameter statistics and a corresponding one of the plural transmission modes. One of the possible subsets of the plurality of transmit antennas and one of the possible subsets of the plurality of receive antennas are then selected based upon criterion predicated at least in part upon the plural output bit error rates and the plural transmission modes. The method further includes connecting one or more of the transmit RF chains to the one of the possible subsets of the plurality of transmit antennas and the one or more receive RF chains to the one of the possible subsets of the plurality of receive antennas.

Some embodiments according to some aspects of the present invention may provide for a criterion that is based on, for example, one or more of the following: an output bit error rate; a transmission mode; a minimization of an output bit error rate; a maximization of a data rate; a maximization of a data rate within a first stage of a receiver; and a minimization of an output bit error rate in a second stage of a receiver.

In the case of a single-channel or spatially-multiplexed MIMO system which uses multiple RF chains at transmit and/or receiver side, certain baseband weighting and combining arrangements may be incorporated within the transmitter (e.g., precoding) and/or receiver together with the selection method. For example, the baseband weights and antenna selection may be both designed such that they contribute to minimize the BER. In another example, the baseband weights may be designed to maximize, for example, an output signal-to-noise ratio (SNR), a signal-to-interference-and-noise ratio (SINR), or a capacity while minimizing BER through appropriate antenna selection.

Some embodiments according to some aspects of the present invention are directed to a channel-adaptive method and/or system for antenna selection based upon minimizing the BER for use in multi-antenna systems, including, for example, N-fold spatially-multiplexed multi-antenna systems. To facilitate appreciation of some embodiments according to some aspects of the present invention, an overview is provided of exemplary architectures that may implement antenna selection within multi-antenna systems. After the overview, additional details relating to system and methods for channel-adaptive antenna selection based on, for example, minimization of BER may be presented.

Architecture for Antenna Selection

Some embodiments according to some aspects of the present invention may be implemented in wireless communication systems in which a smaller number of RF chains are used within a transmitter and/or receiver than the number of transmit/receiver antennas utilized. In some embodiments according to some aspects of the present invention, a number N of receive antenna elements is selected out of a total number of elements M, where M>N. This forms N RF output signals, which are then passed through N RF chains. In an exemplary implementation, each RF chain includes, for example, a filter, downconverter, and A/D converter. The output signals produced by the A/D converter of each RF chain are then digitally processed to generate the N spatially-multiplexed output signals. By performing the requisite selection of a subset of antennas at RF, an N-fold spatially-multiplexed system having more than N receive antennas, but only N RF chains, can be realized at a cost similar to that of a system having N receive antennas. Accordingly, receiver performance may be improved through use of additional antennas at relatively low cost.

A similar technique can be used at a transmitter incorporating N RF chains and a number n_(T) of transmit antennas that is greater than N. In an exemplary implementation the N RF chains are followed by a switch which connects each of them to a subset of N transmit antennas selected out of n_(T), As at the receiver, by performing such selection of a subset of antennas at RF, an N-fold spatially-multiplexed system having more than N transmit antennas, but only N RF chains, can be realized at a cost similar to that of a system having N transmit antennas and N RF chains. Accordingly, transmitter performance may be improved through use of additional antennas at relatively low cost.

A. Spatial Multiplexing

According to some embodiments according to some aspects of the present invention, spatial multiplexing (SM) provides a mode of signal transmission predicated upon the use of multiple antennas at both a transmitter and a receiver in such a way that the bit rate of a wireless radio link may be increased without correspondingly increasing power or bandwidth consumption. In the case in which N antennas are used at both a transmitter and a receiver, an input stream of information symbols provided to the transmitter is divided into N independent substreams. Spatial multiplexing contemplates that each of these substreams will occupy the same “channel” (e.g., a time slot, a frequency or a code/key sequence) of the applicable multiple-access protocol. Within the transmitter, each substream is separately applied to the N transmit antennas and propagated over an intervening multipath communication channel to a receiver. The composite multipath signals are then received by a receive array of N receive antennas deployed at the receiver. At the receiver, a “spatial signature” defined by the N phases and N amplitudes arising at the receive antenna array for a given substream is then estimated. Signal processing techniques are then applied in order to separate the received signals, which permit the original substreams to be recovered and synthesized into the original input symbol stream. The principles of spatially-multiplexed communication and exemplary system implementations are further described in, for example, “Optimum combining for indoor radio systems with multiple users”, by J. H. Winters, IEEE Transactions on Communications, vol. COM-35, no. 11, November 1987, which is hereby incorporated herein by reference in its entirety.

B. Conventional MIMO System

Some aspects of the present invention may be more fully elucidated by first considering a conventional MIMO communication system, which is illustratively represented by FIG. 1. As shown, the MIMO system 100 of FIG. 1 includes a transmitter 110 depicted in FIG. 1 A and a receiver 130 depicted in FIG. 1B. The transmitter 110 and receiver 130 include a set of T transmit RF chains and a set of R receive RF chains, respectively, which are configured to transmit and receive a group of N spatially-multiplexed signals. Within the system 100 it may be assumed that either (i) T is greater than N and R is equal to N; (ii) T is equal to N and R is greater than N; or (iii) both T and R are greater than N.

Referring to FIG. 1A, an input signal S to be transmitted, which typically includes of a stream of digital symbols, is demultiplexed by demultiplexer 102 into N independent substreams S_(1,2 . . . , N). The substreams S_(1,2 . . . , N) are then sent to digital signal processor (DSP) 105, which generates a set of T output signals T_(1,2 . . . , T). The T output signals T_(1,2 . . . , T) are typically generated from the N substreams S_(1,2 . . . , N) by weighting (e.g., multiplying by a complex number) each of the N substreams S_(1,2 . . . , N) by T different weighting coefficients to form NT substreams. These N·T substreams are then combined in order to form the T output signals T_(1,2 . . . , T). The T output signals T_(1,2 . . . , T) are then converted to T analog signals A_(1,2 . . . , T) using a set of T digital-to-analog (D/A) converters 108. Each of the T analog signals A_(1,2 . . . , T) is then upconverted to the applicable transmit carrier RF frequency within a mixer 112 by mixing with a signal provided by a local oscillator 114. The resulting set of T RF signals (e.g., RF_(1,2 . . . , T)) are then amplified by respective amplifiers 116 and transmitted by respective antennas 118.

Referring now to FIG. 1B, the RF signals transmitted by the transmitter 110 are received by a set of R receive antennas 131 deployed at the receiver 130. Each of the R signals received by an antenna 131 is amplified by a respective low noise amplifier 133 and passed through a filter 135. The resultant filtered signals are then each downconverted from RF to baseband using mixers 137, each of which is provided with a signal from local oscillator 138. Although the receiver of FIG. 1B is configured as a homodyne receiver, a heterodyne receiver characterized by an intermediate IF frequency could also be used. The respective R baseband signals produced by the mixers 137 are then converted to digital signals using a corresponding set of R analog-to-digital (A/D) converters 140. The resulting R digital signals D_(1,2 . . . , R) are then weighted and combined using digital signal processor 142 to form N spatially-multiplexed output signals S′_(1,2 . . . , N) which comprise estimates of the transmitted signals S′_(1,2 . . . , N). The N output signals S′_(1,2 . . . , N) are then multiplexed using a multiplexer 155 in order to generate an estimate 160 (S′) of the original input signal S.

C. Antenna Selection at RF in Spatially-Multiplexed Communication Systems

Turning now to FIG. 2, there is shown a block diagram of a MIMO communication system 200 having a transmitter 210 and receiver 250 configured to effect N-fold spatial multiplexing using only N transmit/receive RF chains, even though more than N transmit/receive antennas are respectively deployed at the transmitter 210 and receiver 250. Specifically, the transmitter 210 includes a set of MT transmit antennas 240 and the receiver includes a set of MR receive antennas 260, some embodiments according to some aspects of the present invention may provide that MT and/or MR are greater than or equal to N. For example, (i) MT is greater than N and MR is equal to N; (ii) MT is equal to N and MR is greater than N; or (iii) both MT and MR are greater than N.

As shown in FIG. 2A, an input signal S to be transmitted is demultiplexed by demultiplexer 202 into N independent substreams SS′_(1,2 . . . , N). The substreams SS′_(1,2 . . . , N) are then converted to N analog substreams AS_(1,2 . . . , N) using a corresponding set of D/A converters 206. Next, the N analog substreams AS_(1,2 . . . , N) are upconverted to the applicable transmit carrier RF frequency using a set of mixers 212 provided with the signal produced by a local oscillator 214. The resultant N RF signals (e.g., RF_(1,2 . . . , N)) are then each connected to a selected subset of N transmit antenna elements by a switch 218. The switch 218 connects N RF signals (e.g., RF_(1,2 . . . , N)) to a set of N transmit antennas from the MT available transmit antennas 240, thereby yielding a set of N output signals. A corresponding set of N amplifiers 234 then amplify these N output signals, with the amplified output signals then being transmitted using the N selected transmit antennas 240. In another example, the amplifiers 234 may be located before the switch 218. In this configuration, a total of only N amplifiers is needed instead of a total of MT if one amplifier is placed at each of the MT antennas. The selection of the N antennas is generated so as to minimize the BER of the output signal at the receiver.

Referring to FIG. 2B, the N RF signals transmitted by the transmitter 210 are received by the set of MR receive antennas 260 deployed at the receiver 250. Each of the MR received signals is amplified by a respective low noise amplifier (LNA) 264 and then a subset N of them is connected to a set of N RF chains by a switch 276 in order to form a set of N RF signals which are passed through a corresponding set of N filters 280. In another example, the low noise amplifier 264 may be located after the switch 276 such that the total number of used LNA is N instead of MR if one LNA is placed at all MR receive antenna elements. The resulting N filtered signals are then downconverted to baseband using a set of N mixers 282, each of which is provided with a carrier signal produced by a local oscillator 284. Although the receiver 250 is realized as a homodyne receiver in the embodiment of FIG. 2B, it could also be implemented as a heterodyne receiver characterized by an intermediate IF frequency. (In fact, any of the embodiments according to some aspects of the present invention may incorporate, for example, homodyne configurations or heterodyne configurations). The N baseband signals produced by the mixers 282 are then converted to digital signals via a corresponding set of N A/D converters 286. The N digital signals are then further processed using digital signal processor 288 to form the N spatially-multiplexed output signals SS_(1,2 . . . , N), which are the estimates of the N independent substreams SS_(1,2 . . . , N). The N output signals SS′_(1,2 . . . , N) are then multiplexed via a multiplexer 292 in order to generate the output signal S′, which is an estimate of the input signal S.

In some embodiments according to some aspects of the present invention, a baseband weighting and combining (e.g., a “precoding”) arrangement may be added at the transmitter side for use in conjunction with the antenna selection method discussed below. In this case a DSP block is placed between the demultiplexer 202 and the D/A converters 206, such that the N independent substreams SS_(1,2 . . . , N) are weighted by complex coefficients and combined to form a set of N output signals. These N output signals are then converted into analog signals AS_(1,2 . . . , N) using the corresponding set of D/A converters 206.

In some embodiments according to some aspects of the present invention, space-time coding can be added at the transmitter side for use in conjunction with an exemplary antenna selection method. In this case, the demultiplexer 202 is replaced by a DSP block which processes the input signal S over the space and time domain to form a set of N output signals. These N output signals are then converted into analog signals AS_(1,2 . . . , N) using the corresponding set of D/A converters 206. Among the two most commonly used space-time techniques are 1) the insertion of a time delay (or equivalently a phase-shift) on one or more of the N output signals and 2) the use of the transmit diversity technique described in, for example, “A simple transmit diversity technique for wireless communications”, by S. M. Alamouti, IEEE Journal on Selected Areas in Communications, vol. 16, issue 8, October 1998, pages 1451-1458, which is hereby incorporated herein by reference in its entirety.

Space-time coding techniques may be applicable, for example, to the SC MIMO systems and/or systems designed to yield diversity gain. Precoding techniques may be applicable, for example, to SC-based or spatial-multiplexing-based MIMO systems or systems designed to yield both data rate and diversity gains.

Channel-Adaptive Antenna Selection Method and/or System at RF Based on Minimum Bit Error Rate

A. Overview

Some embodiments according to some aspects of the present invention relate, for example, to a channel-adaptive antenna selection method and/or a channel-adaptive antenna selection system in a multi-antenna communication system predicated on, for example, minimizing a bit error rate. In some embodiments according to some aspects of the present invention, a subset of antenna elements is selected to transmit and/or receive the signals such that the bit error rate is minimized, for example, in a communication system with multiple antennas. Some embodiments according to some aspects of the present invention may provide, in a communication system with multiple antennas, that a subset of antenna elements is selected to transmit and/or receive the signals such that the bit error rate is minimized, for example, over time in the presence of variation in one or more applicable communication channels. Some embodiments according to some aspects of the present invention may be used for antenna selection at the transmitter when multiple antennas are used for transmission. Some embodiments according to some aspects of the present invention can be used for antenna selection at the receiver when multiple antennas are used for reception.

Some embodiments according to some aspects of the present invention may be applicable to, for example, (i) receivers using multiple antennas in what are referred to herein as single channel systems (e.g., system lacking spatial multiplexing); (ii) transmitters using multiple antennas in single channel systems; and (iii) systems in which a smaller number of RF chains are used at the transmitter and/or receiver than the number of transmit and/or receiver antennas in a MIMO system with spatial multiplexing or single-channel.

Some embodiments according to some aspects of the present invention will be described hereinafter with reference to FIGS. 3-7 within the following exemplary contexts: 1) a MIMO system with spatial multiplexing in which a smaller number of RF chains are used at the transmitter and receiver than the number of transmitter/receiver antennas; 2) a single-channel MIMO system without spatial multiplexing in which a smaller number of RF chains are used at the transmitter and receiver than the number of transmitter/receiver antennas; and 3) a single-channel SIMO system without spatial multiplexing containing a receiver using multiple antenna elements. Some embodiments according to some aspects of the present invention may also be employed in the case of a single-channel (SC) multiple-input-single-output (MISO) system without spatial multiplexing in which a transmitter utilizes multiple antenna elements.

For illustrative purposes, the following exemplary examples are described with reference to systems utilizing OFDM modulation (e.g., following the 802.1-1a WLAN standard) or to systems based upon a direct sequence spread spectrum (DS-SS) (e.g., following the WCDMA standard). In certain embodiments according to some aspects of the present invention, the processing capabilities of the DS-SS receiver may be extended to cover the spatial domain through incorporation of a space-time Rake receiver operative to combine multi-path “taps” corresponding to both the temporal and spatial domains. This extension illustrates that the techniques described herein may be generalized to virtually any system employing, for example, temporal and/or frequency domain processing in a frequency-selective fading environment.

B. Antenna Selection in a SM-MIMO-OFDM System

FIG. 3 illustratively represents the transmitter and receiver structure of an SM-MIMO-OFDM system 300 utilizing antenna selection in accordance with an embodiment according to some aspects of the present invention. As shown, two independent sub-streams 304 (e.g., spatially-multiplexed signals) are OFDM-modulated onto Ni frequency sub-carriers and passed through two RF chains 308 to prepare for transmission. At this point, a switching block 312 selects two of four transmit antenna elements 316 to connect to the two RF chains 308. Since only two out of four elements 316 are selected within the transmitter 302, the number of transmit RF chains is advantageously reduced to the number of spatially-multiplexed signals.

In the embodiment of FIG. 3, the switching block 312 contains information identifying the pair of antenna elements 316 to be used for transmission at any given time. The block 312 may compute this information itself (e.g., in the case where the channel 318 is reciprocal) in accordance with an algorithm based upon the minimum BER criterion. In another example, the block 312 may receive the information from the receiver 330 via a feedback path (not shown). This latter approach may be used in the case where the channel 318 is not reciprocal, for example, in an interference-limited environment.

Within the receiver 330, a switching block 334 selects two of four antenna elements 338 to receive incident signals transmitted by the transmitter 302. The switching block 334 connects the two selected antennas 338 to two RF chains 342 operative to convert the two signals into the digital domain for baseband processing. Then, a weight matrix 346 is applied to the received signals at each tone to separate and recover each one of the transmitted spatially-multiplexed signals.

In typical implementations the switching block 334 will be configured to itself compute which pair of antenna elements 338 should be selected for reception by executing an algorithm based upon the minimum BER criterion. In the case where the channel is not reciprocal, the block 334 may be further configured to compute which pair of antenna elements 316 should be used in the transmitter 302 and to provide this information to it. A description of two possible implementations of an antenna selection algorithm executable by the switching blocks 312, 334 is provided with reference to FIGS. 4A and 4B.

Turning now to FIG. 4A, a flowchart is provided of an antenna selection algorithm 400 in which the coding/modulation mode (e.g., data rate or throughput) is fixed or adapted on a long-term basis (e.g., adapted to the large-scale variations of the SNR). The task of the selection algorithm is to select which pair of antenna elements 316 should be used at the transmitter 302 and which pair of antenna elements 338 should be used at the receiver 330 with respect to each packet for the given mode. The selection process may assume, for example, that the channel 318 is quasi-stationary (e.g., the channel 318 is constant over the duration of the packet being transmitted and changes independently between two contiguous packets). Even though the channel 318 may exhibit some frequency selectivity, the antenna selection may be common to the entire frequency bandwidth.

Referring to FIG. 4A, when the transmitter 302 initially powers up (step 401) and the state of the channel 318 is still unknown, a default subset of two of the antenna elements 316 is used to transmit the wireless signal. The receiver 330 similarly uses a default subset of two of the receive antenna elements 338 in order to acquire synchronization. Next, channel state information (CSI) is acquired (step 402). In some embodiments according to some aspects of the present invention, operations to acquire CSI are carried out at the receiver 330. A training sequence composed of known symbols is sent from the transmitter 302 to the receiver 330. At the receiver 330, the channel 318 is estimated based on the received signal and the known sequence of symbols. This operation is carried out as often as the channel 318 changes, for example, at each packet realization. In order for the selection method to be performed successfully, the complete channel matrix should be estimated over the whole frequency bandwidth (e.g., the estimation of the channel path gain from all antenna elements 316 of the transmitter 302 to all antenna elements 338 of the receiver across all tones). Channel estimation techniques based on training sequences applicable to MIMO systems are described in, for example, J. J. Van de Beek et al., “On Channel Estimation in OFDM Systems”, IEEE 45th Vehicular Technology Conference, vol. 2, 25-28 Jul. 1995, pp. 815-819 and A. N. Mody and G. L. Stuber, “Synchronization for MIMO OFDM Systems”, IEEE Globecom 2001, vol. 1, pp. 509-513, which are hereby incorporated herein by reference in their entirety.

Referring again to FIG. 4, mode information is acquired through execution of a link adaptation algorithm (step 404). In the embodiment illustrated by FIG. 4A, the mode change may occur slowly. This enables a link adaptation algorithm to be employed to decide which of the possible mode candidates is best suited to be used in view of the long-term average SNR. Employment of a link adaptation algorithm may ensure that, given a mode selection criterion (e.g., a maximum data rate and a minimum transmit power), the most efficient mode is always used in view of long-term varying channel/SNR conditions. An exemplary link adaptation algorithm capable of being utilized within frequency-selective MIMO systems is described, for example, in “Adaptive Modulation and MIMO Coding for Broadband Wireless Data Networks”, by S. Catreux et al., IEEE Communications Magazine, vol. 40, No. 6, June 2002, pp. 108-115, which is incorporated herein by reference in its entirety. The mode selection may generally be independent of the method of selecting transmitter/receiver antenna elements. The mode may be selected based exclusively upon long-term SNR statistics. Accordingly, it changes at a much slower rate than that at which the antennas are selected. In other words, the selection algorithm may select a new subset of antennas with respect to each packet realization, while the mode changes as a function of long-term SNR variations.

Steps 406, 408 and 410 are repeatedly executed in a loop until all possible combinations of subsets of transmit/receive antenna elements have been evaluated (step 411). For example, considering a MIMO-OFDM system of the type depicted in FIG. 3 (e.g., equipped with 4 transmit antenna elements 316 and 4 receive antenna elements 338), the complete channel matrix can be represented in the frequency domain at tone k by a 4×4 matrix denoted by H_(k). After selection of a subset of two antennas at each side, the sub-channel matrix is reduced in size to a 2×2 matrix denoted by {tilde over (H)}_(k). There are

$\begin{pmatrix} 4 \\ 2 \end{pmatrix} = 6$ possibilities in selecting 2 elements out of a total 2 of 4. Since the antenna selection is applied at both the transmitter 302 and receiver 330, the total number of combinations possible for {tilde over (H)}_(k) is equal to 36. In the general case of a M×M MIMO system being reduced in size to a n×n MIMO system (where M>n), there are

$\begin{pmatrix} M \\ M \end{pmatrix} = \frac{M!}{{n!}{\left( {M - n} \right)!}}$ possibilities in selecting n antenna element from M possible elements. When the selection occurs at both a transmitter and receiver, the total number of combinations for {tilde over (H)}_(k) is equal to

$\left( \frac{M!}{{n!}{\left( {M - n} \right)!}} \right)^{2}.$ This corresponds to the number of iterations of the loop comprised of steps 406, 408 and 410. These iterations may be performed in series (e.g., reusing, common processing resources) or in parallel (e.g., at the expense of additional processing resources). In an exemplary example, all possible antenna combinations could be contemporaneously processed, which might employ a separate processing resource for each possible antenna combination.

Each iteration in the loop comprised of steps 406, 408 and 410 effects processing of one antenna subsystem. First, the 2×2 matrix {tilde over (H)}_(k) is acquired across all tones (k=1, . . . , N₁) for the subsystem of interest (Step 406). The post-processing signal-to-interference-and-noise ratio (SINR) is then computed at each tone k and for each transmitted spatially-multiplexed signal (Step 408). The SINR can most often be found by a closed-form solution dependent upon which signal processing technique is used at the transmitter 302 and/or receiver 330 (e.g., Maximum Ratio Combining (MRC), Minimum Mean Square Error (MMSE), eigen-beamforming, and Maximum Likelihood (ML)). For example, if no spatial processing is implemented at the transmitter 302 and MMSE is applied at the receiver 330, the SINR may be determined as follows:

Compute

${B_{k} = {{{{\overset{\sim}{H}}_{k}^{H}{\overset{\sim}{H}}_{k}} + {\frac{\sigma^{2}}{\sigma_{s}^{2}}I_{2}\mspace{14mu}{with}\mspace{14mu} I_{2}}} = \begin{bmatrix} 1 & 0 \\ 0 & 1 \end{bmatrix}}},$ σ² and σ_(s) ² stand for noise and signal power respectively and k=1, . . . , N_(t) (step 408-1).

Compute C_(k)=1/diag(B_(k) ⁻¹) this is a N×1 vector for each k=1, . . . , N_(t) (step 408-2).

Compute

${SINR}_{k} = {{\frac{\sigma_{s}^{2}}{\sigma^{2}}C_{k}} - 1}$ this is a N×1 vector for each k=1, . . . , N_(t) (step 408-3).

In step 410, the SINR information is converted into BER information in view of the current mode (see, e.g., step 404). Since the BER may be a complicated function of the channel 318 and of the coding/modulation and antenna combining techniques used, an approximation of the BER may be used. The approximation may also be a function of the channel 318 and of the applicable coding/modulation and antenna combining techniques. The BER over the packet (e.g., at the output of the Viterbi decoder if coding is used) for transmitted substream i may be expressed as a non-linear, unknown function ƒ of the set of SINR_(k), k=1, . . . , N_(t), for example: BER_(i) =ƒ({SINR_(k) ^(i)}),i=1, . . . ,N;k=1, . . . ,N _(t)

Next, the function ƒ is approximated by some known function. Specifically, the output BER is approximated by the average of the bit error rate over the channel, for example:

$\begin{matrix} {\overset{\_}{{BER}_{i}} \approx {{1/N_{t}}{\sum\limits_{k = 1}^{N_{t}}\;{BER}_{k}^{i}}}} & (1) \end{matrix}$ where BER_(k) ^(i) is the bit error rate given the SINR at tone k for spatially-multiplexed substream i. In another example, BER_(k) can also be the bit error rate given the signal-to-noise ratio at tone k. The average may also be taken in the time domain where BER_(k) is the bit error rate given the SINR at channel time sample k. BER_(k) may be the bit error rate with respect to a given signal component (e.g., a signal tone or tap delay).

Furthermore, BER_(k) is also approximated by some simple closed-form function. Through simulations it has been found that for mode 1 of 802.1-1a (e.g., BPSK, R1/2), the behavior of the average bit error rate BER with respect to the SINR or SNR (in some examples, the BER normalization factor 1/N_(t) may be omitted, since it does not affect the antenna selection) can be modeled, for example, by:

$\begin{matrix} {{{\overset{\_}{{BER}_{i}} \approx {- {\sum\limits_{k = 1}^{N_{t}}\;{\tanh\;\left( {SINR}_{k}^{i} \right)}}}};{i = 1}},\ldots\mspace{14mu},N} & (2) \end{matrix}$ The BER at signal component k has been approximated by −tan h(SINR_(k)).

The tan h function may not always adequately approximate the BER, particularly for different modulation techniques. Some of the following functions may generally afford better approximations when using particular techniques:

1) The BER of an uncoded BPSK modulation in AWGN channel is (see, e.g., J. G. Proakis, Digital Communications, 3^(rd) Ed. McGraw-Hill Series, 1995)

${BER}_{BPSK} = {{Q\left( \sqrt{\frac{2\; E_{b}}{N_{o}}} \right)} = {{Q\left( \sqrt{2\;\gamma_{b}} \right)} = {{\frac{1}{2}{{erfc}\left( \sqrt{\gamma_{b}} \right)}} = {\frac{1}{2}{{erfc}\left( \sqrt{\gamma_{s}} \right)}}}}}$ The shape of the function erfc is reasonably approximated by the function (as compared to y=−tan h(x)) y=−[(1−e ^(−2√{square root over (x)}))+(1−e ^(−1.8x))]

2) The BER of an uncoded QPSK modulation in AWGN channel is (see, e.g., J. G. Proakis, Digital Communications, 3^(rd) Ed. McGraw-Hill Series, 1995)

${BER}_{QPSK} = {{Q\left( \sqrt{\frac{2\; E_{b}}{N_{o}}} \right)} = {{Q\left( \sqrt{2\;\gamma_{b}} \right)} = {{\frac{1}{2}{{erfc}\left( \sqrt{\gamma_{b}} \right)}} = {\frac{1}{2}{{erfc}\left( \sqrt{\frac{\gamma_{s}}{2}} \right)}}}}}$ The shape of erfc(√{square root over (x/2)}) is better approximated by the function: y=−[(1−e ^(−1.3√{square root over (x)}))+(1−e ^(−x))] than by y=−tan h(x).

3) The BER of an uncoded 16QAM modulation in AWGN channel may be derived from the symbol error rate (SER) given, for example, in J. G. Proakis, Digital Communications, 3^(rd) Ed. McGraw-Hill Series, 1995 as

${BER}_{16\;{QAM}} = {{1 - \sqrt{1 - {\frac{3}{2}{Q\left( \sqrt{\frac{3\; E_{s}}{15\;{No}}} \right)}}}} = {1 - \sqrt{1 - {\frac{3}{4}{{erfc}\left( \frac{\gamma_{s}}{10} \right)}}}}}$ An appropriate fitting function is y=−(1−e^(−0.2x)).

4) The BER of an uncoded 64QAM modulation in AWGN channel may be derived from the symbol error rate (SER) given, for example, in J. G. Proakis, Digital Communications, 3rd Ed. McGraw-Hill Series, 1995 as

${BER}_{64\;{QAM}} = {{1 - \left( {1 - {\frac{7}{4}{Q\left( \sqrt{\frac{\gamma_{s}}{21}} \right)}}} \right)^{\frac{1}{3}}} = {1 - \left( {1 - {\frac{7}{8}{{erfc}\left( \sqrt{\frac{\gamma_{s}}{42}} \right)}}} \right)^{\frac{1}{3}}}}$ An appropriate fitting function is y=−(1−e^(−0.35√{square root over (x)})).

It is to be understood than any fitting function that reasonably models the behavior of the BER versus SINR can be used in equation (2). The number of appropriate fitting functions is not limited to the few examples given above.

As mentioned above, steps 406 to 410 are iteratively performed until all possible combinations of subsets of antennas are considered (step 411). At the conclusion of this iterative process, a set of N estimates of BER values (one for each spatially-multiplexed signal) for all

$\frac{M!}{{n!}{\left( {M - n} \right)!}}\left( {{or}\left( \frac{M!}{{n!}{\left( {M - n} \right)!}} \right)}^{2} \right)$ possible antennas combinations is obtained. It then remains to select the subset of antennas that minimize the mean over the set of BERs, the maximum over the set of BERs or, the minimum of the set of BERs (step 412).

$\min\mspace{14mu}{antennas}\mspace{14mu}{combinations}\mspace{14mu}\begin{Bmatrix} {mean} \\ {{i = 1},\ldots\mspace{14mu},N^{\{{BER}_{i}\}}} \end{Bmatrix}$ $\min\mspace{14mu}{antennas}\mspace{14mu}{combinations}\mspace{14mu}\begin{Bmatrix} \min \\ {{i = 1},\ldots\mspace{14mu},N^{\{{BER}_{i}\}}} \end{Bmatrix}$ $\min\mspace{14mu}{antennas}\mspace{14mu}{combinations}\mspace{14mu}\begin{Bmatrix} \max \\ {{i = 1},\ldots\mspace{14mu},N^{\{{BER}_{i}\}}} \end{Bmatrix}$

FIG. 4B is a flowchart of an antenna selection algorithm 500 in which the coding/modulation mode may be changed as frequently as once per packet realization in response to corresponding changes in the channel 318. In this example, the coding/modulation mode is adapted at the same rate as antenna selection is effected.

Referring to FIG. 4B, steps 501 and 502 are similar to steps 401 and 402, respectively. As shown, steps 504 through 510 comprise a loop that is iteratively executed until all possible combinations of subsets of antennas have been evaluated. It follows that the number of iterations

$\frac{M!}{{n!}{\left( {M - n} \right)!}}$ of this loop is equivalent to (e.g., selection at one end of the link) or

$\left( \frac{M!}{{n!}{\left( {M - n} \right)!}} \right)^{2}$ (e.g., selection at both ends of the link). In this regard steps 504 and 506 are similar to steps 406 and 408, respectively. Based upon the knowledge of the instantaneous SINR at all tones, a link adaptation block determines the most efficient mode for each spatially-multiplexed signal, given a mode selection criterion (e.g., a maximum data rate and a minimum transmit power) (step 508). This step is similar to step 404, with the exception that the mode decision is made based upon instantaneous SNR (or SINR) statistics rather than upon long-term SNR (or SINR) statistics. As a result, different combinations of subsets of antennas may yield different mode decisions. Finally, given the instantaneous SINR and mode information, step 510 computes or determines the corresponding BER in the same manner as was described above with reference to step 410.

Again, steps 504 through 510 are performed until all possible combinations of subsets of antennas are considered (step S11). Once this has occurred, a set of N estimates of BER values (e.g., one for each spatially-multiplexed signal) for all

$\frac{M!}{{n!}{\left( {M - n} \right)!}}\left( {{or}\left( \frac{M!}{{n!}{\left( {M - n} \right)!}} \right)}^{2} \right)$ possible antennas combinations is obtained. The selection algorithm 500 differs from the algorithm 400 in that the

$\frac{M!}{{n!}{\left( {M - n} \right)!}}\left( {{or}\left( \frac{M!}{{n!}{\left( {M - n} \right)!}} \right)}^{2} \right)$ possible antennas combinations do not necessarily use the same coding/modulation mode. The decision of which antennas subset to select therefore depends not only on a minimization of the BER but also on the mode (e.g., data rate or throughput). Several exemplary options are provided with regard to the final decision of selecting a subset of antenna elements pursuant to step S12 of the selection algorithm 500: Option 1

1) Group all combinations of subsets of antennas using the same mode into a common pool.

2) Choose the pool corresponding to the highest mode (yielding maximum data rate).

Within that pool, select the combination of subset of antennas that minimizes the BER in a manner substantially similar to that described with reference to Step 412.

Option 2

Regardless of which mode is used by each combination, select the combination of antenna subsets that minimizes the BER in a manner substantially similar to that described with reference to Step 412.

Option 3

Implement a hybrid version of option 1 and 2, for example:

1) Group all combinations of subsets of antennas using the same mode into a common pool.

2) Choose the X pools corresponding to the X highest modes (yielding maximum data rate), where X is an integer equal to 1, or 2 or 3, etc.

3) Within these pools, select the combination of subset of antennas that minimizes the BER in a manner substantially similar to that described with reference to step 412.

FIG. 5 illustratively represents the packet error rate (PER) as function of SNR resulting from employment of an exemplary antenna selection technique within a SM-MIMO-OFDM system operative in a noise-limited environment. The results of FIG. 5 may be applicable, for example, to a system using tour transmit and receive antennas in the manner exemplified by FIG. 3. The results reflect, as merely exemplary examples, a packet size of 1000 bytes and a fixed coding/modulation mode. The results also reflect that two exemplary RF chains are incorporated within both the applicable transmitter and receiver. In addition, the results of FIG. 5 use BPSK modulation, a coding rate of ½ (e.g., mode 1 of 802.11a), a channel model characterized as “channel A” (e.g., 50 ns rms delay spread, 0.5 antenna correlation), and a fitting function of tan h.

The legend for the curves in FIG. 5 is as follows:

2×2 2SM-MIMO MMSE:

This system corresponds to a SM-MIMO-OFDM system using 2 transmit and 2 receive antennas together with 2 spatially-multiplexed (SM) signals. Since the number of antennas is equal to the number of SM signals, no antenna selection is applied. A baseband combining arrangement is used at the receiver to separate the two substreams, e.g., MMSE.

4×4 2SM-MIMO sel mcap MMSE:

This system corresponds to a SM-MIMO-OFDM system using 4 transmit and 4 receive antenna elements together with 2 spatially-multiplexed (SM) signals. A conventional selection method is applied at both the transmitter and receiver to select a subset of 2 antenna elements among four, according to a maximum capacity criterion. After the selection at the receiver, MMSE is applied at baseband to separate the two substreams.

2×4 2SM-MIMO sel mber MMSE (Bound):

This system corresponds to a SM-MIMO-OFDM system using 2 transmit and 4 receive antenna elements together with 2 spatially-multiplexed (SM) signals. A selection method is applied only at the receiver end to select a subset of 2 antenna elements among four, according to the minimum BER criterion. In this case, no fitting function is used to approximate the BER. Instead, the BER is assumed to be known perfectly. This case may not be readily implemented, but rather provides a bound on the performance which may be achieved through use of some embodiments according to some aspects of the present invention.

4×4 2SM-MIMO sel mber MMSE (Bound)

This system corresponds to a SM-MIMO-OFDM system using 4 transmit and 4 receive antenna elements together with 2 spatially-multiplexed (SM) signals. A selection method is applied at both transmit and receive sides to select a subset of 2 antenna elements among four, according to the minimum BER criterion. In this case, no fitting function is used to approximate the BER. Instead, the BER is assumed to be known perfectly. This case may not be readily implemented, but rather provides a bound on the performance which may be achieved through use of some embodiments according to some aspects of the present invention.

4×4 2SM-MIMO sel mber MMSE (Implementation tan h)

This system corresponds to a SMMIMO-OFDM system using 4 transmit and 4 receive antenna elements together with 2 spatially-multiplexed (SM) signals. A selection method according to some embodiments according of the present invention is applied at both transmit and receive sides to select a subset of 2 antenna elements among four, according to a minimum BER criterion. The fitting function to approximate the BER is tan h.

The results illustratively represented by FIG. 5 show that all systems using some type of antenna selection provide gains relative to systems with no selection, and that antenna selection based upon minimum BER provides significantly more gain than selection based upon the maximum capacity criterion. Specifically, at a PER level of 10e-2 and with antenna selection in accordance with the present invention being applied at both the transmitter and receiver, a 7.6 dB gain is achieved relative to a system with no selection and 4.2 dB gain is demonstrated relative to a system in which selection is based on maximum capacity. When selection is applied consistent with some embodiments according to some aspects of the present invention at only the receiver, the resulting performance is seen to be between that achieved when no selection is employed and that which occurs when selection is employed at both the transmitter and receiver. Finally, the performance of the system in accordance with some embodiments according to some aspects of the present invention very closely approaches a theoretical performance bound illustrated by FIG. 5.

C. Antenna Selection in a SC-MIMO-OFDM System

FIG. 6 illustrates a SC-MIMO-OFDM system 600 which utilizes precoding techniques in addition to an exemplary antenna selection method according to some embodiments of the present invention. In the embodiment of FIG. 6, precoding refers to various baseband weighting and combining arrangements performed at a transmitter 602. Referring to FIG. 6, a single-stream of symbols 604 is weighted by a set of complex coefficients 608 and combined to produce a set of N output signals where N refers to the number of RF chains 612 used within the transmitter 602. These N output signals are then passed through the N RF chains 612 in order to produce N RF signals. These N RF signals are then coupled to a corresponding group of N of M transmit antenna elements 616 via a switch 620 and transmitted through a channel 624.

At a receiver 622, a set of N of M receive antenna elements 626 is selected via a switch 630 to receive the incoming signals communicated through a channel 624. The N RF receive signals are then processed by N RF chains 634 and converted to the digital domain for baseband processing to recover the original transmitted signal.

Some embodiments according to some aspects of the present invention may provide, for example, that the baseband weights 608 and antenna selection method are designed to collectively contribute to the minimization of the BER. Some embodiments according to some aspects of the present invention may provide, for example, that the baseband weights 608 may be chosen to maximize the output SNR (or SINR) or capacity, while the antenna selection is conducted so as to minimize the BER. The right and left singular vectors of the sub-channel matrix {tilde over (H)}_(k) corresponding to the largest singular value may be used to select optimal subsets of transmit antenna elements 616 and receive antenna elements 626 as well as the appropriate transmit baseband weights 608 and receive baseband weights 640. Determination of baseband weighting values in the context of MIMO systems lacking antenna selection has been described, for example, in J. B. Andersen, IEEE Antennas and Propagation Magazine, vol. 42, no. 2, April 2000, pp. 12-16, which is incorporated herein by reference in its entirety.

The exemplary embodiment illustrated in FIG. 6 may be modified by replacing the baseband weights 608 within the transmitter 602 by a space-time coding block. In this case, an antenna selection method may be employed to select the subset of antennas in both the transmitter and receiver in accordance with some embodiments of the present invention. In addition, the space-time coding block processes the input stream of symbols as described in, for example, “A simple transmit diversity technique for wireless communications”, by S. M. Alamouti, IEEE Journal on Selected Areas in Communications, vol. 16, issue 8, October 1998, pages 1451-1458, which is incorporated herein by reference in its entirety.

D. Antenna Selection in a DS-SS-SIMO System

FIG. 7 depicts a receiver 700 of a DS-SS SIMO system having two receive antenna elements 704 (n_(R)=2). The receiver 700 integrates RAKE receiver functionality together with an exemplary antenna selection process. As shown, the receiver 700 is equipped with only a single RF chain 708 disposed to be connected to only one of the two receive antenna elements 704 at any given time via a switch 712. The choice of which of the two elements 704 to connect to the RF chain 708 is made based upon the minimum BER criterion. Some embodiments according to some aspects of the present invention may provide that the received signal BER corresponding to each receive antenna element 704 is computed and the element 704 yielding the minimum value of BER is selected. Since the BER may typically comprise a complicated function of the applicable channel and of the coding/modulation and antenna combining techniques used, the BER for a given channel and antenna combining technique is approximated such that it varies as a function of the coding/modulation method used.

Once the optimal one of the antenna elements 704 has been selected, the RAKE receiver behaves in the same way as if it were implemented in a single-input single-output (SISO) system (e.g., one antenna at each end of the link). The RAKE receiver uses a plurality of J correlators 720 (e.g., J=2 in FIG. 7), each of which corresponds to one of the first J separable multipath components. Each such multipath component is associated with a time delay τ_(j), j=1, . . . , J, respectively. The output of each correlator 720 (e.g., a finger) is then weighted 730 and combined 740 to form a single output received signal 750 comprising an estimate of the transmitted signal.

In one exemplary example, the received signal corresponding to the i^(th) antenna element 704 at the input of the RAICE receiver may be expressed as:

$\begin{matrix} {{r_{i}(t)} = {{\sum\limits_{l = 1}^{L_{i}}\;{h_{i,1}\sqrt{2\;{Pd}}\left( {t - \tau_{i,l}} \right){p\left( {t - \tau_{i,l}} \right)}{\cos\left( {{w_{0}\left( {t - \tau_{i,l}} \right)} - \theta_{i,l}} \right)}}} + {n_{i}(t)}}} & (3) \end{matrix}$ where L_(i) is the number of taps in the channel received at the i^(th) antenna element 704, h_(i,l) is the complex channel gain at antenna i and tap l, P is the signal transmit power, d is the data sequence comprised of symbols of period T, and p is the spreading sequence composed of chips of period T_(c)=T/G, where G is the spreading factor. In addition, τ_(i,l) is the path delay associated with tap l and antenna i, w₀ corresponds to the carrier frequency w₀=2πf₀, and θ_(i,l) is the phase shift corresponding to tap l and antenna i. The noise n_(i) measured at the i^(th) antenna element 704 is modeled as an AWGN process with two-side spectral density N₀/2. For the sake of simplicity and clarity of expression, equation (3) assumes a single-user environment. However, the present invention need not be so limited and also contemplates being applied in the presence of multiple users.

At the output of the correlator 720 of the j^(th) finger, the received signal may be represented as:

$\begin{matrix} {r_{i,j} = {{\sqrt{\frac{2}{T}}{\int_{\tau_{j}}^{\tau_{j}}{{r_{i}(t)}{p\left( {t - \tau_{j}} \right)}{\cos\ \left( {{w_{0}\left( {t - \tau_{j}} \right)} - \theta_{j}} \right)}{\mathbb{d}t}}}} = {{\sqrt{PT}h_{i,j}d_{0}} + n_{i,j}}}} & (4) \end{matrix}$ where d₀ is the desired symbol to be demodulated, and n_(i,j) is the AWGN noise component with zero-mean and with two-side spectral density N₀/2. Again for purposes of simplicity and clarity of presentation, it was assumed in equation (4) that there is no interpath interference (IPI). However, the present invention also contemplates being used in the presence of IPI.

Following diversity combining, the final output of the RAKE receiver corresponding to the i^(th) antenna element 704 is:

$\begin{matrix} {r_{i} = {\sum\limits_{j = 1}^{J}\;{w_{i,j}r_{i,j}}}} & (5) \end{matrix}$ where J is the number of RAKE fingers and where the optimum combining weights are generally chosen so as to match the channel, for example: w _(i,j) =h* _(i,j)  (6)

In this case, the RAKE performs maximum ratio combining and the SNR at the RAKE output, corresponding the i^(th) antenna element 704 is given by

$\begin{matrix} {\gamma_{i} = {\sum\limits_{j = 1}^{J}\;\gamma_{i,j}}} & (7) \end{matrix}$ where γ_(i,j) is the post-combining SNR on the j^(th) path associated with the i^(th) antenna element 704. Based on (4), γ_(i,j) may be expressed by:

$\begin{matrix} {\gamma_{i,j} = {{\frac{{h_{i,j}}^{2}P}{\sigma^{2}}\mspace{14mu}{where}\mspace{14mu}\sigma^{2}} = {\frac{N_{0}}{2} \cdot \frac{2}{T}}}} & (8) \end{matrix}$ is the noise power.

The BER at the output of the RAKE receiver corresponding to the i^(th) antenna element 704 may be obtained from the knowledge of the probability density function (PDF) of γ_(i,). For example, if no coding is used and BPSK modulation is applied to the data sequence in accordance with the methodology described, for example, in “Digital Communications”, J. G. Proakis, 3^(rd) Edition, McGraw-Hill Series, 1995, the BER is found by integrating the conditional error probability represented by Q(√{square root over (2γ_(i))}) over the PDF of γ_(l) for example:

$\begin{matrix} {{BER}_{i} = {\int_{0}^{\infty}{{Q\left( \sqrt{2\;\gamma_{i}} \right)}{p_{\gamma}\left( \gamma_{i} \right)}\ {\mathbb{d}\gamma_{i}}}}} & (9) \end{matrix}$

Once the BER is estimated for all receive antennas, the antenna element 704 yielding the minimum BER is selected: min{BER_(i)} i=1, . . . n _(R)  (10) where n_(R) represents the total number of receiver antenna elements.

As will be readily appreciated, as coding is added to the system (e.g., turbo coding, convolution coding) and other modulation levels are used, the modeling function used in (9) to estimate the BER will need to change. Some embodiments according to some aspects of the present invention may provide that any fitting function which accurately models BER behavior for a given system may be used by an exemplary antenna selection algorithm. The fitting function will generally be dependent upon parameters including, for example, one or more of the following: the channel, coding and modulation used, signal processing at transmit and/or receiver side, receiver SNR and other parameters.

The exemplary embodiment illustrated in FIG. 7 may be extended to a two-dimensional RAKE receiver in which processing is conducted in both the space and time domain. In this context, an exemplary antenna selection algorithm may be incorporated to select a subset of N antennas (N>1), from a total of M antennas (M>N), which minimize the BER at the output of the 2D-RAKE.

While the present invention has been described with reference to certain embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the scope of the present invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the present invention without departing from its scope. Therefore, it is intended that the present invention not be limited to the particular embodiments disclosed, but that the present invention will include all embodiments falling within the scope of the appended claims. 

What is claimed is:
 1. A transmitter, comprising: a first chain configured to transmit a first signal; a second chain configured to transmit a second signal; and a switching block configured to couple the first chain and the second chain to a first and a second antenna, respectively, from among a plurality of antennas, based on transmission of the first and the second signals satisfying a first set of performance statistics, wherein the first set of performance statistics is indicative of improved transmission performance compared to a second set of performance statistics, the second set of performance statistics corresponding to the first chain and the second chain being coupled to other antennas from among the plurality of antennas that are different from the first and the second antennas.
 2. The transmitter of claim 1, wherein the switching block is further configured to calculate the first set of performance statistics.
 3. The transmitter of claim 1, wherein the first set of performance statistics is a first and a second output bit-error rate (BER) corresponding to the transmission of the first and the second signals.
 4. The transmitter of claim 3, wherein the first and the second output BER are less than an output BER corresponding to the first chain and the second chain being coupled to the other antennas from among the plurality of antennas that are different from the first and the second antennas.
 5. The transmitter of claim 3, wherein the switching block is further configured to measure a channel parameter statistic and a transmission mode corresponding to the first and the second signals, and wherein the first and the second output BERs are calculated utilizing the channel parameter statistic and the Transmission mode.
 6. The transmitter of claim 5, wherein the channel parameter statistic comprises: a signal-to-noise ratio (SNR) or a signal-to-interference-and-noise-ratio (SINR) corresponding to the first and the second signals.
 7. The transmitter of claim 3, wherein the first and the second signals include a plurality of frequencies, and wherein the switching block is further configured to approximate the first and the second output BERs based on a signal-to-noise ratio (SNR) or a signal-to-interference-plus-noise-ratio (SINR) at a single frequency from among the plurality of frequencies.
 8. The transmitter of claim 7, wherein the switching block is further configured to approximate the first and the second output BERs by evaluating an average BER as a closed form function of the SNR or the SINR over the plurality of frequencies.
 9. The transmitter of claim 1, wherein the switching block is further configured to receive the first set of performance statistics via feedback from a receiver, the receiver being configured to receive the first and the second signals.
 10. The transmitter of claim 1, wherein the switching block is further configured to repeat the coupling of the first and the second chains until all antenna pair combinations from among the plurality of antennas have been coupled to the first and the second chains, and wherein the first set of performance statistics is indicative of a most-improved transmission performance compared to all other antenna pair combinations from among the plurality of antennas that are different from the first and the second antennas.
 11. In a transmitter, a method comprising: propagating a first signal through a first chain; propagating a second signal through a second chain; coupling the first and the second chains to a first pair of antennas from among a plurality of antennas to form a first transmission state associated with a first set of performance statistics; coupling the first and the second chains to a second pair of antennas from among the plurality of antennas to form a second transmission state associated with a second set of performance statistics; and transmitting the first and the second signals in the first or the second transmission state based on which of the first or the second set of performance statistics indicates better transmission performance.
 12. The method of claim 11, wherein the first set of performance statistics is a first and a second output bit-error rate (BER) corresponding to the transmission of the first and the second signals in the first transmission state.
 13. The method of claim 11, wherein the second set of performance statistics is a first and a second output bit-error rate (BER) corresponding to the transmission of the first and the second signals in the second transmission state.
 14. The method of claim 11, further comprising: calculating the first and the second set of performance statistics based on sub-channel information associated with the first and the second signals.
 15. The method of claim 11, further comprising: measuring a channel parameter statistic and a transmission mode corresponding to the first and the second signals.
 16. The method of claim 15, further comprising: calculating the first and the second set of performance statistics utilizing the channel parameter statistic and the transmission mode.
 17. The method of claim 15, wherein the measuring the channel parameter statistic comprises: measuring a first-order statistic, a second-order statistic, or a higher-order statistic.
 18. The method of claim 15, wherein the measuring the channel parameter statistic comprises: measuring a signal-to-noise ratio (SNR) or a signal-to-interference-and-noise-ratio (SINR) corresponding to the first and the second signals.
 19. The method of claim 11, further comprising: receiving the first and the second set of performance statistics via feedback from a receiver.
 20. The method of claim 11, further comprising: repeating the coupling of the first and the second chains for all antenna pair combinations from among the plurality of antennas to form a plurality of transmission states having a plurality of respective sets of performance statistics, and wherein the transmitting comprises: transmitting the first and the second signals in a transmission state from among the plurality of transmission states based on which of the plurality of respective sets of performance statistics is indicative of a most-improved transmission performance. 